Selected Neural Plasticity References How Therapy Changes the Human Brain Martha S. Burns, Ph.D.,ccc-slp Joint Appointment Professor Northwestern University Bryck & Fisher (2012) Training the Brain: Practical Applications of Neural Plasticity From the Intersection of Cognitive Neuroscience, Developmental Psychology and Prevention Science. Am Psychol. 67(2): 87 100 Review as applied to perdiatrics Kerr, AL, Cheng, SY, Jones, TA (2011) - Experience-dependent neural plasticity in the adult damaged brain. Commun Disord. 44(5): 538 548 Kleim, Jeffrey (2011) Neural plasticity and neurorehabilitation: Teaching the new brain old tricks. Journal of communication disorders, 44(5) Kleim, J. and Jones, T.A. (2008) Principles of experience-dependent neural plasticity. JSHR 51(1), S225-S239. Murphy & Corbett (2009) Plasticity during stroke recovery: from synapse to behaviour. Nature Reviews Neuroscience Pekna,M., Pekny, M., Nilsson,M.(2012) Modulation of Neural Plasticity as a Basis for Stroke Rehabilitation. Stroke 43: 2819-2828 Thorough review for all disciplines Takeuchi, N & Izumi, S (2013) Rehabilitation with Poststroke Motor Recovery: A Review with a Focus on Neural Plasticity. Stroke Research and Treatment. Volume 2013, Article ID 128641 Excellent review for PT and OT Warraich Z, Kleim JA. (2010) Neural plasticity: the biological substrate for neurorehabilitation. PM R. 2:S208 S219., Reference Source for more specific Neural Plasticity Rehabilitation Research Chapman, Sandra Bond (2013) Make Your Brain Smarter. New York: Free Press, Chapter 11.Cognitive skills Chen, A. et al. (2011) Training of goal-directed attention regulation enhances control over neural processing for individuals with brain injury. Brain 134, 1541 1554 Attention Gabrielli, J. et al. (2015) Prediction as a Pragmatic and Humanitarian Contribution from Human Cognitive Neuroscience Neuron. Volume 85, Issue 1, Pages 11-26 Prediction Kim, Y-H et al. (2009) Plasticity of the Attentional Network after Brain Injury and Cognitive Rehabilitation. Neurorehabilitation and Neural Repair (23) 468-477 Attention Johansson BB. Current trends in stroke rehabilitation. A review with focus on brain plasticity. Acta Neurol Scand. 2011;123:147 159. Patel, R. Spreng, RN & Turner, F. (2012) Functional Brain Changes Following Cognitive and Motor Skills Training: A Quantitative Meta-Analysis. Neurorehabilitation and Neural Repair Oct. 23. Motor Skills Tye, Kay (2014) Neural Circuit Reprogramming: A New Paradigm for Treating Neuropsychiatric Disease? Neuron 83, 1259-1261 Neuropsychiatric disease Vas, A., Chapman, S. et al. (2011) Higher Order Reasoning Training Years After Traumatic Brain Injury in Adults. Journal of Head Trauma Rehabilitation 26(3) 224-239. Cognitive skills Vinogradav, et al., (2012) Cognitive Training for Impaired Neural Systems in Neuropsychiatric Illness. Neuropsychopharmacology. 37(1): 43 76.Perception References of neurochemistry of plasticity Neuron (2012) 76(1) Reviews on Neuromodulatory Mechanisms Ott, T. et al. (2014) Dopamine receptors differentially enhance rule coding in primate prefrontal cortex neurons. Neuron 11.012 1
References on issues related to when to begin treatment after stroke Dromerick, A.W. et al.(2009) Very Early Constraint-Induced Movement during Stroke Rehabilitation. Neurology 73;195-201 Holland, A & Fridriksson, J. (2001) Aphasia management during the early phases of recovery following stroke. American Journal of Speech - Language Pathology; 10, 1 Turkstra, Lyn (2013) Inpatient cognitive rehabilitation, is it time for a Change? Journal of Head Trauma Rehabilitation.Vol. 28, No. 4, pp. 332 336 Experience-Dependent Plasticity of the Cerebral Cortex (Pekna,M., Pekny, M., Nilsson,M.,2012) The ability to adapt in response to the changing environment is the most fundamental property of the nervous tissue and constitutes the basis for learning. Neural plasticity - neurobiological basis for ability to adapt & learn in an experience-dependent manner At the structural level, neural plasticity could be defined in terms of dendritic and axonal arborization, spine density, synapse number and size, receptor density, and in some brain regions also the number of neurons. Experience-Dependent Plasticity of the Cerebral Cortex The structural constituents of neural plasticity jointly determine the complexity of neuronal networks and their activity and contribute to habilitation of skills in the developing brain as well as recovery of function after stroke and other CNS injury Hebbian Axiom - Neurons that fire together wire together in networks 2
Cortical map development - Normal A1 development Cortical Map Rearrangements Occurs in sensory systems within the cortex including auditory and visual The reorganization that occurs after rehabilitation is associated with upregulation chemical neuromodulators in relation to the parameters of the stimulation that occurred Zhang, Bao & Merzenich, Nature Neurosci 2001 Zhang, Bao & Merzenich, Nature Neuroscience, 2001 But beyond early infancy, plasticity is modulated as a function of: 1. novelty 2. attention 3. judgment of error 4. punishment 5. Reward 6. et alia Different dimensions of adult cortical plasticity are enabled by the behaviorallycontext-dependent release of: acetylcholine (focused attention/reward) (Kilgard, Bao) dopamine (reward, novelty) (Bao) norepinephrine (novelty) (Bollinger) serotonin (Bollinger) et alia See Kilgard & Merzenich, Science (1998) Kilgard & Merzenich, Nature Neuroscience (1999) Bao, Merzenich, et al, Nature (2001) In infants, exposure-based plasticity is relatively uniform. In adults, learning-induced changes are complexly nuanced by differences in behavioral context that result in the differential release of 6 or 7 modulatory neurotransmitters. 3
In older animals and humans, the brain controls its own plasticity. acetylcholine-enabled plasticity dopamine (VTA) enabled plasticity. I. Reward follows stimulus II. Reward precedes stimulus. Kilgard & Merzenich Science, 1998 Bao, Merzenich et al (2001) Nature Cortical Map Rearrangements (Pekna,M., Pekny, M., Nilsson,M.,2012) When normal input to a specific area of the primary somatosensory cortex is altered because of genetics or because of experience rapid structural and functional reorganization results in this area being activated by sensory stimulation of the surrounding intact body regions Gerloff, et al. (2006) Multimodal imaging in chronic stroke Brain 129, 791 808 801 Fig. 7 Detailed illustration of enhanced rcbf during right (recovered) hand movements in stroke patients (n = 9) compared with age-matched controls (n = 9) in the contralesional central region. 4
Neuroimaging research on effects of therapy Early research on constraint induced therapy after paralysis Neuroimaging research on effects of therapy In developing brains Language and reading disorders In adult brains after injury especially visual working memory training Power attained by combining bottom-up and topdown processing activities Taub Model Importance of Intensive Intervention Taub Constraint Induced therapy E Taub, G Uswatte, R Pidikiti - Journal of rehabilitation (1999); J Liepert, H Bauder, WHR Miltner, E Taub, C Weiller - Stroke, 2000; E Taub, G Uswatte, T Elbert - Nature Reviews Neuroscience, 2002 5
(Temple et al., 2001; Gaab, 2008) And the effects of treatment indicate functional connections seen in nonimpaired readers are achieved (DeHaene, Reading in the Brain,pp 260) Inferior Frontal Region Phonological area Left anterior inferior frontal gyrus Left Inferior Parietal Lobe Visual Word Form Area Visual Word Form Area Specific characteristics of effective language based therapies Figure 1. Training-related effects on brain activation and dopamine receptor density from neuroimaging studies. (a) Increases in frontal and parietal activity after training of WM (reproduced with permission from [33]). (b) Increased activity in the caudate nucleus after training of WM tasks requiring updating (reproduced with permission from [ The emerging consensus from neuroscience is that combining of cognitive (executive function) top down interventions with bottomup (perceptual and attention) interventions may be most effective 6
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